BACKGROUND OF THE INVENTION
1. Field of the Invention
[0001] The present invention relates to a zoom lens and, more particularly, to a zoom lens
having refractive and diffractive optical elements.
2. Description of Related Art
[0002] Zoom lenses have been utilized in the art for quite some time. The zoom lenses at
the telephoto mode magnify an object being viewed to provide the viewer with a view
of a distant scene. On the other hand, the zoom lenses at the wide field of view modes
cover very wide angle scenes. Generally, the zoom lenses are formed from refractive,
reflective or a combination of refractive and reflective elements. The packaging of
the zoom lens generally dictates the type of optical elements which are present.
[0003] Generally, in an all refractive zoom lens assembly, the assembly includes several
lens groups. Turning to Figure 1, a first lens group 1, which is called a focusing
group, is used to relay an outside scene onto an intermediate plane. The second lens
group 2, which is known as a variator, is generally a virtual relay and is used to
vary the magnification of the zoom lens. Ordinarily, it is regarded as the "engine"
of the zoom lens. The variator is moved back and forth to change the effective focal
length of the system. A third lens group 3 is used to compensate for the focus shift
introduced during the zoom process and is generally referred to as a compensator.
For many zoom lens systems, the wavefront emerging from the compensator is either
collimated or near collimated. The fourth lens group 4 is referred to as a prime group.
The fourth lens group 4 is used to focus the wavefront emerging from the compensator
onto a viewing plane. Also, some zoom lenses combine the compensator 3 and prime group
4 as a single unit.
[0004] U.S. Patent No. 3,784,284, issued January 8, 1974 to Nakamura, illustrates a zoom
lens like that described above. While providing a zoom lens having a varying focal
length, the zoom lens has several disadvantages. One disadvantage is that it is an
all-refractive lens and is heavy and bulky. The lens has a effective focal length
range from 7.5 mm to 56.3 mm. Also, the main limitation dominating the complexity
of this type of lens system is chromatic aberration correction. At the long effective
focal length zoom positions, axial chromatic aberration and spherochromatism are the
limiting aberrations. At the short effective focal length zoom positions, lateral
chromatic aberration is the dominating aberration. In order to stabilize the chromatic
aberration during zoom, each group requires flint-glass lenses to either partially
or fully correct the chromatic aberration. The chromatic aberration correction of
the focusing group and the variator is particularly critical. Unfortunately, each
group can evolve to a form which is bulky and complicated and this takes away from
the available zoom space. Therefore, the zoom range is seriously jeopardized. In addition,
some residual third and higher order aberrations are created as a result of steeper
lens curvatures.
[0005] EP-A- 441,206 discloses a lens employing aspherical and binary grating optical surfaces
which can be switched between a wide field of view and a narrow field of view.
SUMMARY OF THE INVENTION
[0006] Accordingly, the new and improved optical zoom system of the present invention provides
the art with improved aberration reduction. Zoom lenses of the present invention have
reduced levels of third and higher order residual monochromatic aberrations. The present
invention provides a zoom lens with a wider zoom range, a simpler optical form and
provides a more compact package. Also, the present invention reduces the weight of
the moving lens element groups. Thus, the present invention provides a zoom lens which
is lighter weight, relatively less expensive, and more agile during the zoom process
with a wider zoom range.
[0007] In the preferred embodiment of the invention, the zoom lens includes a first lens
group for relaying an outside scene to an intermediate plane. A second lens group
is positioned to receive the wavefront from the first lens group. The second lens
group varies the magnification of the zoom lens. Also, the second lens group includes
at least one diffractive optical element. A third lens group compensates for focus
shift and focuses the wavefront onto the viewing plane.
[0008] Generally, the third lens group is broken down into a third and fourth lens groups.
The third lens group compensates for focus shift and the fourth lens group focuses
the wavefront on the viewing plane. The third lens group would also include a diffractive
optical element.
[0009] From the subsequent description and the appended claims taken in conjunction with
the accompanying drawings, other objects and advantages of the present invention will
become apparent to those skilled in the art.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] In the accompanying drawings:
[0011] FIG. 1 is a schematic view of a relevant art refractive zoom lens system.
[0012] FIG. 2 is a schematic view of a zoom optical system in accordance with the present
invention.
[0013] FIG. 3 is a schematic view like that of FIG. 2 at an intermediate focal length.
[0014] FIG. 4 is a schematic view like that of FIG. 2 at a minimum focal length.
DESCRIPTION OF THE PREFERRED EMBODIMENT
[0015] Turning to FIGS. 2 through 4, a zoom optical lens system is illustrated and designated
with the reference numeral 10. The system 10 includes a first lens group 12, a second
lens group 14, a third lens group 16 and a fourth lens group 18. The lens groups focus
an image on a viewing plane 20.
[0016] The first lens group, commonly referred to as the focusing group, includes three
lenses. The lens 22, lens 24 and lens 26 of the focusing group are generally positioned
on an optical axis 50 defined by the lens 22. Generally, the lens 22, lens 24 and
lens 26 are convex-concave, biconvex and convex-concave lenses, respectively. The
lenses 22, 24 and 26 are formed from SF13, LAK7 and BK7 glass materials, respectively.
All the lenses have a predetermined radius of curvature on their front and back surfaces
of the lens. Also, the lenses have a predetermined thickness at their vertexes and
predetermined aperture sizes on their front and back surfaces.
[0017] The second group of lenses 14 which is generally referred to a variator, includes
a pair of optical elements. The variator lens 28 and lens 30 optical elements are
generally centered on the optical axis 50. The lens 28 is generally a biconcave lens
formed from a LF5 glass material. The lens 28 has a predetermined radius of curvature
on its front and back surfaces. Also, the lens 28 has a predetermined thickness at
its vertex and predetermined aperture sizes on its front and back surfaces.
[0018] The variator lens 30 is a refractive-diffractive hybrid optical element. The refractive-diffractive
optical element is formed from a BK7 material. The refractive-diffractive optical
element generally has a concave front surface and a planar back surface. The surfaces
have a predetermined radius of curvature. Also, the lens has a predetermined thickness
at its vertex and predetermined aperture sizes on its front and back surfaces. The
refractive-diffractive hybrid optical element 30 is likewise positioned on the optical
axis 50. The diffractive optical element of the hybrid lens 30 is a kinoform or kinoform
equivalent Fresnel zone plate. Although the Fresnel zone plate can be imprinted on
either a planar surface or curved surface, a planar surface is generally easier for
fabrication.
[0019] The third lens group 16, generally referred to as the compensator, includes a pair
of optical elements. The compensator first optical element lens 32 is generally a
biconvex lens formed from a LAKN7 glass material. The lens 32 has a predetermined
radius of curvature on its front and back surfaces. Also, the lens 32 has a predetermined
thickness at its vertex and a predetermined aperture size on its front and back surfaces.
[0020] The optical element 34 is a refractive-diffractive hybrid optical element. Generally,
the optical element 34 has a convex planar configuration formed from a LAK11 material.
The element 34 has a predetermined radius of curvature on its front and rear surfaces
as well as a predetermined thickness at its vertex and predetermined aperture sizes
on its front and back surfaces.
[0021] The variator 14 and compensator 16 move with respect to one another to multiple positions
between the first and fourth lens group as seen in FIGS. 2 through 4. As the variator
and compensator move, the effective focal length of the system is changed.
[0022] The fourth lens group 18, generally referred to as the prime group, includes five
lenses. The lenses 36, 38, 40, 42 and 44 are centered with respect to the optical
axis 50. Also, this group focuses the radiation emerging from the compensator 16 to
the viewing plane 20. Generally, the lenses 36, 38, 40, 42 and 44 are biconcave, cube,
biconvex, biconvex and concave-convex, respectively. Each lens has a predetermined
radius of curvature on its front and back surface as well as a predetermined thickness
at its vertex and predetermined aperture sizes on its front and back surfaces. The
cube 38 is generally a beam-splitting device to sample the radiation emerging from
the previous lenses.
[0023] Generally, the focusing group relays an image of an outside scene to the viewing
plane. The variator varies the magnification of the wavefront, including an image
of the scene, as it passes through the system. The compensator acts on the wavefront
to compensate for focus shift of the wavefront as it passes through the system. The
prime group then focuses the wavefront onto the viewing plane 20.
[0024] The zoom system illustrated in FIGS. 2 through 4 is in the same optical space as
the zoom system of FIG. 1. The effective focal length range of the zoom system of
FIG. 1 is from 7.5 mm to 56.3 mm, as illustrated in phantom. The present system provides
an effective focal length between 7.5 mm to 75 mm in the same optical space, thus,
the present zoom provides a 10:1 magnification ratio compared to the 7.5:1 range of
the relevant art. This is a 33% extension in the zooming range through the use of
the optical arrangement of the present invention.
[0025] A specific prescription for a zoom lens configuration is given in the following table:
TABLE 1
| Optical Prescription |
| Element Number |
Surface Number |
Radius of Curvature |
Thickness |
Glass |
| Lens 22 (S1-S2) |
S1 |
80.5125 |
1.40000 |
Ohara SF13 |
| Lens 24 (S2-S3) |
S2 |
43.3484 |
9.50000 |
Ohara LAK7 |
| |
S3 |
-217.721 |
|
|
| Gap |
|
|
0.100000 |
Air |
| Lens 26 (S4-S5) |
S4 |
41.6851 |
3.40000 |
Schott BK7 |
| |
S5 |
61.4151 |
|
|
| Gap |
|
|
Z1 |
Air |
| Lens 28 (S6-S7) |
S6 |
-900.577 |
0.900000 |
Schott LF5 |
| |
S7 |
19.2063 |
|
|
| Gap |
|
|
3.93483 |
Air |
| Lens 30 (S8-S9) |
S8 |
-17.5096 |
0.800000 |
Schott BK7 |
| |
S9 |
Infinite |
0.000000 |
Diffractive |
| |
|
|
|
Optical Element 1 |
| Gap |
|
|
Z2 |
Air |
| Lens 32 (S10-S11) |
S10 |
661.786 |
2.90000 |
Schott LAKN7 |
| |
S11 |
-29.0168 |
|
|
| Gap |
|
|
0.100000 |
Air |
| Lens 34 (S12-S13) |
S12 |
28.5963 |
5.50000 |
Ohara LAK11 |
| |
S13 |
0.000000E+00 |
0.00000 |
Diffractive |
| |
|
|
|
Optical Element 2 |
| Gap |
|
|
Z3 |
Air |
| Lens 36 (S14-S15) |
S14 |
-20.6652 |
0.800000 |
Schott BK7 |
| |
S15 |
14.5234 |
|
|
| Gap |
|
|
1.20000 |
Air |
| Lens 38 (S16-S17) |
S16 |
0.000000E+00 |
8.30000 |
Schott LF7 |
| |
S17 |
0.000000E+00 |
|
|
| Gap |
|
|
8.90000 |
Air |
| Lens 40 (S18-S19) |
S18 |
659.103 |
3.90000 |
Schott LAKN7 |
| |
S19 |
-19.2241 |
|
|
| Gap |
|
|
0.200000 |
Air |
| Lens 42 (S20-S21) |
S20 |
29.6660 |
5.30000 |
Schott SK16 |
| Lens 44 (S21-S22) |
S21 |
-22.6192 |
1.20000 |
Schott SF6 |
| |
S22 |
-180.939 |
|
|
| Gap |
|
|
22.30180 |
Air |
| Plane 20 |
|
|
|
|
The wavefront information of both diffractive optical elements 1 and 2 is ƒ
1(ρ) and ƒ
2(ρ), respectively
Where ρ is the radial coordinate of aperture in the unit of mm,

and

The zone plate ring boundaries of the diffractive optical element 1 are located at

Similarly, the zone plate ring boundaries of the diffractive optical element 2 are
at

The selected diffractive orders for the diffractive optical elements 1 and 2 are
+1 order and -1 order, respectively
(+) Radii have centers to the right
(-) Radii have centers to the left
Thickness is axial distance to next surface
Dimensions are given in millimeters
Reference Wavelength = 0.58756 µm
Spectral Range is from 0.48610 µm to 0.65627 µm
| Group Space |
| EFL (mm) |
Z1 (mm) |
Z2 (mm) |
Z3 (mm) |
| 7.503 |
1.729 |
48.861 |
0.980 |
| 21.798 |
20.828 |
24.401 |
6.341 |
| 74.994 |
34.184 |
2.555 |
14.831 |
[0026] It should be noted that the above prescription is an example for illustrative purposes
and should not be construed in any way to limit the present invention.
[0027] An advantage of the present invention is that the zoom lens is able to vary the magnification
continuously and may be used in several optical sensors. The present invention may
be utilized in this display technology area such as the color projection optics for
the next generation of flight simulators. The present invention provides a wide range
zoom to simulate the range changes of both the target and the scene. Also, the present
invention may be utilized as a photographic zoom lens.
[0028] While it will be apparent that the preferred embodiment is well calculated to fill
the above stated objects, it will also be appreciated that the present invention is
susceptible to modification, variation, alteration and change without varying from
the proper scope and fair meaning of the subjoined claims.
1. A zoom lens (10) comprising:
first lens group means (12) for relaying an outside scene to an intermediate plane;
second lens group means (14) for varying magnification of the relayed image from the
first lens group (12) ; and
third lens group means (16, 18) for compensating for focus shift and to focus the
wavefront onto the viewing plane, characterised in that said second lens group means
(14) includes at least one diffractive optical element (30).
2. The zoom lens according to Claim 1 wherein said third lens group means (16, 18) includes
at least one diffractive optical element (34).
3. The zoom lens according to Claim 1 wherein said third lens group means (16, 18) includes
a first lens sub-group (16) to compensate for focus shift and a second lens sub-group
(18) to focus the wavefront on said plane.
4. The zoom lens according to Claim 1 wherein said second lens group means comprises
moving means to change the effective focal length of the zoom lens.
5. The zoom lens according to Claim 3 wherein said first lens sub-group (16) includes
at least one diffractive optical element (34).
6. The zoom lens according to Claim 3 wherein said second lens group also includes at
least one refractive optical element (28).
7. The zoom lens according to Claim 6 wherein said diffractive optical element (30) is
positioned between said refractive optical element (28) and said first lens sub-group
(16).
8. The zoom lens according to Claim 5 wherein said first lens sub-group (16) includes
at least one refractive optical element (32).
9. The zoom lens according to Claim 8 wherein said first lens sub-group diffractive optical
element (34) is positioned between said refractive optical element (32) and said second
lens sub group (18).
1. Ein Zoomobjektiv (10) mit:
einer ersten Linsengruppeneinrichtung (12) zum Übertragen einer Außenszene zu einer
Zwischenebene;
einer zweiten Linsengruppeneinrichtung (14) zum Variieren des Abbildungsfaktors des
von der ersten Linsengruppe (12) übertragenen Bildes; und
einer dritten Linsengruppeneinrichtung (16, 18) zum Kompensieren einer Fokusverschiebung
und um die Wellenfront auf die Betrachtungsebene zu fokussieren, dadurch gekennzeichnet,
daß die zweite Linsengruppeneinrichtung (14) wenigstens ein lichtbeugendes optisches
Element (30) aufweist.
2. Das Zoomobjektiv nach Anspruch 1, dadurch gekennzeichnet,
daß die dritte Linsengruppeneinrichtung (16, 18) wenigstens ein lichtbeugendes optisches
Element (34) aufweist.
3. Das Zoomobjektiv nach Anspruch 1, dadurch gekennzeichnet,
daß die dritte Linsengruppeneinrichtung (16, 18) eine erste Linsenuntergruppe (16)
aufweist, um eine Fokusverschiebung zu kompensieren, und eine zweite Linsenuntergruppe
(18), um die Wellenfront auf die Ebene zu fokussieren.
4. Das Zoomobjektiv nach Anspruch 1, dadurch gekennzeichnet,
daß die zweite Linsengruppeneinrichtung eine Bewegungseinrichtung aufweist, um die
effektive Brennweite des Zoomobjektivs zu verändern.
5. Das Zoomobjektiv nach Anspruch 3, dadurch gekennzeichnet,
daß die erste Linsenuntergruppe (16) wenigstens ein lichtbeugendes optisches Element
(34) aufweist.
6. Das Zoomobjektiv nach Anspruch 3, dadurch gekennzeichnet,
daß die zweite Linsengruppe ebenfalls wenigstens ein lichtbrechendes optisches Element
(28) aufweist.
7. Das Zoomobjektiv nach Anspruch 6, dadurch gekennzeichnet,
daß das lichtbeugende optische Element (30) zwischen dem lichtbrechenden optischen
Element (28) und der ersten Linsenuntergruppe (16) angeordnet ist.
8. Das Zoomobjektiv nach Anspruch 5, dadurch gekennzeichnet,
daß die erste Linsenuntergruppe (16) wenigstens ein lichtbrechendes optisches Element
(32) aufweist.
9. Das Zoomobjektiv nach Anspruch 8, dadurch gekennzeichnet,
daß das lichtbeugende optische Element (34) der ersten Linsenuntergruppe zwischen
dem lichtbrechenden optischen Element (32) und der zweiten Linsenuntergruppe (18)
angeordnet ist.
1. Objectif à longueur focale variable (10) comprenant:
un premier groupe de lentilles (12) pour relayer une scène extérieure à un plan intermédiaire;
un second groupe de lentilles (14) pour faire varier l'agrandissement de l'image relayée
du premier groupe de lentilles (12);
un troisième groupe de lentilles (16,18) pour compenser le changement de convergence
des rayons de lumière et pour mettre au point l'onde enveloppe sur le plan de visée,
caractérisé en ce que ledit second groupe de lentilles (14) comprend au moins un élément
optique diffractif (30).
2. Objectif à longueur focale variable selon la revendication 1, dans lequel ledit troisième
groupe de lentilles (16,18) comprend au moins un élément optique diffractif (34).
3. Objectif à longueur focale variable selon la revendication 1, dans lequel ledit troisième
groupe de lentilles (16,18) comprend un premier sous-groupe de lentilles (16) pour
compenser le changement de convergence des rayons de lumière et un second sous-groupe
de lentilles (18) pour mettre au point l'onde enveloppe sur ledit plan.
4. Objectif à longueur focale variable selon la revendication 1, dans lequel ledit second
groupe de lentilles comprend des moyens mobiles pour changer la distance focale effective
de l'objectif à longueur focale variable.
5. Objectif à longueur focale variable selon la revendication 3, dans lequel ledit premier
sous-groupe de lentilles (16) comprend au moins un élément optique diffractif (34).
6. Objectif à longueur focale variable selon la revendication 3, dans lequel ledit second
groupe de lentilles comprend également au moins un élément optique réfractif (28).
7. Objectif à longueur focale variable selon la revendication 6, dans lequel ledit élément
optique diffractif (30) est situé entre l'élément optique réfractif (28) et ledit
premier sous-groupe de lentilles (16).
8. Objectif à longueur focale variable selon la revendication 5, dans lequel ledit premier
sous-groupe de lentilles (16) comprend au moins un élément optique réfractif (32).
9. Objectif à longueur focale variable selon la revendication 8, dans lequel l'élément
optique diffractif (34) du premier sous-groupe de lentilles est situé entre ledit
élément optique réfractif (32) et ledit second sous-groupe de lentilles (18).